RESUMO
Background: Adipose tissue provides an abundant source of multipotent cells, which represent a source of cell-based regeneration strategies for urinary bladder smooth muscle repair. Our objective was to confirm that adipose-derived stem cells (ADSCs) can be differentiated into smooth muscle cells. Methods: In this study, adipose tissue samples were digested with 0.075% collagenase, and the resulting ADSCs were cultured and expanded in vitro. ADSCs at passage two were differentiated by incubation in smooth muscle inductive media (SMIM) consisting of MCDB I31 medium, 1% FBS, and 100 U/mL heparin for three and six weeks. ADSCs in non-inductive media were used as controls. Characterisation was performed by cell morphology and gene and protein expression. Result: The differentiated cells became elongated and spindle shaped, and towards the end of six weeks, sporadic cell aggregation appeared that is typical of smooth muscle cell culture. Smooth muscle markers (i.e. alpha smooth muscle actin (ASMA), calponin, and myosin heavy chain (MHC)) were used to study gene expression. Expression of these genes was detected by PCR after three and six weeks of differentiation. At the protein expression level, ASMA, MHC, and smoothelin were expressed after six weeks of differentiation. However, only ASMA and smoothelin were expressed after three weeks of differentiation. Conclusion: Adipose tissue provides a possible source of smooth muscle precursor cells that possess the potential capability of smooth muscle differentiation. This represents a promising alternative for urinary bladder smooth muscle repair.
Assuntos
Tecido Adiposo , Células-Tronco , Células Musculares , Regeneração , Bexiga UrináriaRESUMO
For treatment of benign prostatic hyperplasia [BPH], Plasma Kinetic loop Resection of the Prostate [PKRP] is an alternative to conventional monopolar transurethral resection of prostate [TURP]. We compared outcomes with the two treatments in a randomized trial. Over a one-year period, we randomly assigned patients with an indication for surgery for BPH and who met inclusion criteria to treatment with either PKRP or TURP. We measured prostate volume by transrectal ultrasound, relief of bladder outlet obstruction, operative time, decline in serum sodium and hemoglobin, weight of resected prostatic chips, duration of catheterization and hospital stay. Patients were evaluated one month after discharge for obstructive symptoms. Complications were also recorded. Of 102 patients enrolled, 51 underwent PKRP and 51 underwent TURP. Relief of obstructive symptoms and mean operative time showed no statistically significant difference. The PKRP group had a smaller decline in hemoglobin than the TURP group [0.6 g/dL vs 1.8 g/dL, P=.01], a lower reduction in serum sodium levels [1.03 mmol/L vs 5.01 mmol/L, P=.01], a shorter catheterization time [37.2 hours versus 57.7 hours, P=.03] and a shorter hospital stay [1.5 days versus 2.6 days, P=.02]. One patient in the bipolar PKRP group needed recatheterization versus four patients in the TURP group. PKRP reduces morbidity with an outcome similar to conventional monopolar TURP in the treatment of BPH